JPH03188784A - Incoming data communication signal controller for cable television system - Google Patents

Abstract

PURPOSE:To always keep a stable incoming signal level by giving a correction data to decide an output level of an incoming signal to a terminal equipment from a center station in addition to a reference data and allowing the terminal equipment to manage the level of the incoming signal automatically at the terminal equipment itself. CONSTITUTION:An incoming signal level from a terminal equipment in a center station 100 is detected by an incoming signal detector 106 and inputted to a control section 105. The control section 105 discriminates whether or not the level of the incoming signal from a terminal equipment is within a specified range. For example, when the level is higher than the specified level, a command to decrease the incoming signal level and a signal representing the correction are sent to a relevant terminal equipment. When a characteristic correction command and a correction quantity are sent from the center station 100 are sent to the terminal equipment 300, the current correction data is corrected by the designated correction form a new correction data. Then according to the new correction data curve, the output level of the incoming signal is set automatically.

Description

DETAILED DESCRIPTION OF THE INVENTION [Purpose of the Invention (Industrial Application Field) This invention relates to a cable television system (hereinafter referred to as a CATV system) equipped with a two-way communication function, in which an uplink signal transmitted from a terminal device is used. The present invention relates to an uplink data communication signal control device for a cable television system that stabilizes data communication signals.

(Prior Art) In addition to broadcasting television signals, CATV systems are equipped with a two-way communication function that enables communication between a center station and terminals to mutually send and receive service data, etc. There is. CATV with this function
The system is referred to as a bidirectional addressable CATV system.

FIG. 5 shows an overview of a bi-directional addressable CATV system. Broadcast signals from the center station 1 are guided to a branch 5 via a trunk cable 8 and bidirectional trunk amplifiers 2 to 4 along the way. The signal is introduced from the branch 5 via a drop cable 9 to a terminal 7 at a subscriber's home 6. The upstream signal is guided to the center station 1 through a route opposite to that of the broadcast signal and the downstream signal.

FIG. 6 shows the internal configuration of the center station 1 and the terminal 7.

A broadcast equipment section 10 is installed in the center station 1, and the broadcast signal from this broadcast equipment section 10 is transmitted to a bidirectional distributor 11.
The signal is sent to the trunk cable 8 via the main cable 8. Also, signals sent from the terminal via the trunk cable 8 (upstream signals)
is introduced into the data communication signal modulator/demodulator 13 via a bidirectional distributor 11.12. The uplink data demodulated here is introduced into the control unit 14 and decoded. Further, the level of the upstream signal distributed by the bidirectional distributor 12 is detected by the upstream signal detector 15, and the level information is input to the control unit 14. The center station 1 can also transmit downlink data to terminals. The downlink data is
The data communication signal is outputted from the control unit 14 and transmitted to the modulator/demodulator 13.
The signal is input to the main cable 8, modulated into a downstream signal, and sent to the trunk cable 8 through the bidirectional distributor 12.11.

At the terminal 7, the broadcast signal and downlink signal from the drop cable 9 are introduced via a bidirectional distributor 16.

The channel of the broadcast signal is selected in the television signal selection section 17, and the selected channel signal is sent to the terminal 1.
8 to the television receiver. Further, the downlink signal is introduced into the data communication signal demodulator 20 via the bidirectional distributor 16, 19, demodulated, becomes downlink data, and introduced into the control section 21, where it is decoded. Uplink data to be transmitted from the terminal 7 to the center station 1 is output from the control unit 21, manually modulated by the data communication signal modulator 23, and sent as an uplink signal to the drop cable 9 via the bidirectional distributor 19.16. Sent out.

(Problems to be Solved by the Invention) In a bidirectional addressable CATV system, when a terminal is installed, level adjustment is performed in order to transmit an upstream signal from the terminal to the center station 1. There are two methods for this adjustment.

The first method is to check the level of the fJ signal sent from the center station l to the terminal when the terminal is installed, and set the output level of the terminal according to the degree of attenuation.

In other words, the degree of attenuation of the upstream signal transmitted from the terminal to the center station is estimated based on the degree of attenuation of the downlink signal from the center station 1, and the terminal is adjusted so that the level of the upstream signal at the center station is within a predetermined range. I'm making adjustments.

The second method, as shown in FIG. 6, is to add an uplink signal detector 15 to the center station 1, use this detector 15 to detect the detection level of the uplink signal, and detect the level of the uplink signal according to this level. This is a method of transmitting control data for setting the transmission level of upstream signals. As a result, the terminal 7 automatically controls the output level of the upstream signal.

However, both methods have problems.

In other words, according to the first method, once the transmission output level of the -degree terminal is set, it is fixed after that, so if there is a level change in the trunk system, such as a drift due to temperature or a change over time, the center station will change the transmission output level from each terminal. On the way up, the level of the issue varies greatly.

Furthermore, if the level of the upstream signal from the terminal exceeds the permissible range, it is necessary to go to the subscriber's home and make adjustments again.

According to the second method, the upstream signal output level of the terminal is automatically controlled, but as the number of subscribers increases, the time required for level control increases in the total data communication time, and the data communication speed increases. There is a problem that there is a relative decline in Therefore, if the number of times the uplink signal output level from the terminal is controlled is reduced, the variation in the output level of each terminal will increase. Therefore, according to the conventional system, there is no problem in data communication using the sequential polling method, which allows variation in the upstream signal level at the center station, but it is possible to collect data generated at each subscriber terminal more quickly. This becomes a problem when introducing methods such as fractional polling (which requires minimizing level differences for collision detection).

Therefore, this invention aims to provide a cable television system that reduces the number of times that the center station directly controls the terminal side, allows the terminal itself to automatically manage the upstream signal level, and maintains a stable upstream signal level at all times. The object of the present invention is to provide an uplink data communication signal control device.

[Structure of the Invention] (Means for Solving the Problems) The present invention transmits downlink signals from the modulation section of a center station to a plurality of terminals, and sends uplink signals from the modulation sections of the plurality of terminals to the center station. In a cable television system having a two-way communication function in which the center station and the terminal are provided with means for receiving and demodulating each other's signals, the terminal is provided with a means for detecting the level of the downlink signal from the center station. level means for setting the level of the upstream signal to have a negative correlation with the level of the downlink signal, storage means for storing correction data transmitted from the center station, and the reference and correction data. and level setting means for setting an upstream signal level based on the level detected by the level detection means.

(Function) With the above means, in addition to the reference data, the center station provides the terminal with correction data for determining the output level of the uplink signal, while the terminal monitors the level of the downlink signal from the center station. Therefore, the output level of the upstream signal can be automatically controlled based on the characteristics based on the reference and correction data.

(Example) Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows an embodiment of the present invention. 100 is a center station, which is connected to a terminal 300 via a cable path 200. Although only one terminal is shown in the drawing, there are actually multiple terminals.

A broadcast equipment section 101 is installed in the center station 100, and broadcast signals from the broadcast equipment section 101 are connected to a cable path 200 via a bidirectional distributor 102. In addition, the signal (uplink signal) transmitted from the terminal via the cable path 200 is transmitted to the bidirectional distributor 102.10.
4 to the data communication signal modulator/demodulator 103.

The uplink data demodulated here is introduced into the control section 105 and decoded. Furthermore, the level of the upstream signal distributed by the bidirectional distributor 104 is detected by the upstream signal detector 106, and the level information is input to the control unit 105. Furthermore, the center station 100 can also transmit downlink data to the terminals. The downlink data is output from the control section 105 and input to the data communication signal modulation/demodulator 103, where it is modulated and becomes a downlink signal, which is transmitted to the bidirectional distributor 104.1.
02 to cable path 200.

Next, the terminal 300 side will be explained.

Broadcast signals and downlink signals from cable path 200 are introduced into bidirectional distributor 301 . One terminal of the bidirectional distributor 301 is connected to a television signal selection section 302. In the channel selection section 302, a CATV channel is selected based on the channel selection data from the control section 307, and frequency conversion is performed.

And the television signal of the selected channel is at terminal 303.
and supplied to the television receiver.

The other terminal of the bidirectional distributor 301 is connected to the bidirectional distributor 30
Connected to 4. One terminal of the bidirectional distributor 304 is further connected to a bidirectional distributor 305 and a data communication signal modulator 309.

One terminal of the bidirectional distributor 305 is connected to a data communication signal demodulator 306, and the other terminal is connected to a downstream signal level detector 308.

Therefore, the downlink signal transmitted from the center station 100 is demodulated by the data communication signal demodulator 306, and the demodulated data is introduced into the control section 307. Further, the level of this downlink signal is detected by a downlink signal level detector 308, and the detection signal is introduced into the control section 307. Further, uplink data to be transmitted to the center station 100 is transmitted to the control unit 30.
7 to a data communication signal modulator 309, where it is modulated into an upstream signal and sent to the cable path 200 via a distributor 304, 301. 311 is connected to the control port. This embodiment is constructed as described above. First, the basic concept of this device will be explained.

As for the uplink signal sent by the terminal 300, as the route loss increases, the human power level at the center station 10o decreases. The same can be said about downlink signals.

Therefore, in order to obtain a stable upstream signal level at the input section of the center station 100, the level of the upstream signal must be controlled with the characteristics shown in FIG. 2, for example, with respect to the input level of the downstream signal at the terminal 300. It's a good thing.

It is expected that the physical distance between the center station 100 and each terminal will vary greatly. For this reason, fluctuations in the transmission characteristics become large, so the standard correction data curve R
For, the correction data (±K) for the standard correction data
need to be added.

Therefore, in this embodiment, for the uplink signal output control function of the terminal 300, the standard correction data curve R shown in FIG. 2 is first set in advance, that is, stored in a memory (not shown). Therefore, in this state, the terminal 300 automatically controls the output level of the uplink signal according to the standard correction data curve R according to the input level of the downlink signal, and the input level at the center station 100 is maintained at a predetermined level. That will happen.

In terminal 300, uplink signal level control is performed as follows. The control unit 307 controls the downlink signal level detector 3
The detection signal from 08 is determined, and the gain of the amplifier in the output stage of the data communication signal modulator 309, for example, is controlled according to this detection level.

By the way, the correction data curve employed in terminal 300 is not limited to the standard one.

It becomes necessary to modify the correction data curve depending on the physical distance from the center station 100. In such a case, the center station 100 corrects the correction data curve (±K).
will be held.

This correction need not be made all the time, but may be done when the number of terminals is significantly increased or decreased, or during a specific service period.

FIG. 3 shows a signal processing routine used in the center station 100 when correcting the correction pig curve.

The upstream signal level from the terminal is detected by the upstream signal detector 106, and the detected level information is manually input to the control unit 105. The control unit 105 determines whether the level of the upstream signal from the terminal is within a specified range (step Al). If it is outside the specified range, it is determined whether the level is higher or lower than the specified level (step A2). If the level is higher than the specified level, a characteristic modification command (instruction to lower the upstream signal level) and a signal indicating the amount of modification are sent to the corresponding terminal as a downstream signal (step A3). Conversely, if the level is lower than the specified level, a characteristic modification command (instruction to raise the upstream signal level) and a signal indicating the amount of modification are sent to the corresponding terminal as a downstream signal (step A4).

As a result, the correction data curve is corrected within the ± range shown in FIG.

FIG. 4 shows a signal processing routine used when the correction data curve is modified in terminal 300.

In step Bl, it is determined whether or not a characteristic correction command and correction amount have been sent from the center station 100. If so, in step B2, the current correction data is corrected by the specified correction amount, and a new corrected data. Then, the output level of the upstream signal is set according to the input level of the downstream signal from the center station 100 and the new correction data curve (step B3). As a result, the uplink signal transmission level of the terminal is set, and the uplink signal is transmitted (step B4). After this, the output level of the upstream signal is automatically set according to the new correction data curve.

As described above, in this embodiment, the center station 100 provides correction data to the terminal, so that the terminal can automatically adjust the output level of the uplink signal. As a result, the control burden on the center station 100 for managing the level of uplink signals is significantly reduced. Furthermore, since the time required to control the level of the upstream signal is reduced, the problem of lowering the data communication speed is also solved. Furthermore, since the output level of the upstream signal is automatically and adaptively adjusted at the terminal, the level of the upstream signal at the center station will not vary due to temperature fluctuations or line load fluctuations.

In this embodiment, the standard correction data is stored in the terminal in advance, but it may be transmitted from the center to the terminal in the same way as the correction data. Further, the correction data may change the slope of the correction data curve R.

[Effects of the Invention] As explained above, according to the present invention, the number of times that the center station directly controls the terminal side is reduced, and the terminal itself automatically manages the level of the upstream signal, thereby providing a stable upstream signal at all times. level can be maintained.

[Brief explanation of drawings]

FIG. 1 is a configuration explanatory diagram showing an embodiment of the present invention, FIG. 2 is a characteristic diagram showing an example of a correction data curve of an uplink signal in a terminal according to the present invention, and FIGS. 3 and 4 are diagrams of a center station, respectively. and an explanatory diagram of the signal processing routine of the terminal, Fig. 5 is a diagram showing an overview of the CATV system, and Fig. 6 is a diagram showing the conventional CATV system.
1 is a diagram showing the configuration of a center station and terminals of an ATV system. 100... Center station, 200... Cable route,
300...Terminal, 101...Broadcast equipment department, 102.
104.301.304.305...bidirectional distributor,
103...Data communication signal modulation demodulator, 105...
Control unit, 106... Uplink signal detector, 302... Television signal selection unit, 306... Data communication signal demodulator, 307... Control unit, 308... Downlink signal level detector, 309 ...Data communication signal modulator.

Claims (1)

[Claims] The modulation section of the center station sends downlink signals to a plurality of terminals, the modulation sections of the plurality of terminals send out uplink signals to the center station, and the center station and the terminals have mutual communication with each other. In a cable television system having a two-way communication function equipped with means for receiving and demodulating signals, the terminal includes a level means for detecting the level of a downlink signal from the center station, and a level means for detecting the level of the downlink signal from the center station, and a level means for detecting the level of the downlink signal from the center station; storage means for storing reference data for setting uplink signal levels to have a correlation and correction data transmitted from a center station; and a storage means for storing correction data transmitted from a center station, based on the reference and correction data and the level detected by the level detection means. 1. An uplink data communication signal control device for a cable television system, comprising level setting means for setting an uplink signal level.